In a vapor delivery device, a carrier or an expedient for an active ingredient is a liquid that can be vaporized by exposure to a concentrated, focused heating point using an efficient electrical power source. The device may have a vaporizing element and an electrical power source in a housing. A switch controls supply of electrical power to the vaporizing element from the electrical power source. A tube connects a liquid reservoir to the vaporizing element. A first valve, a second valve, and a pump are generally associated with the tube. A lever pivotally supported on or in the housing may be positioned to operate the first valve, the second valve, the pump and the switch, via pivoting movement of the lever. The device efficiently provides a uniform dose of vapor with each actuation.
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1. A vapor delivery device comprising:
a housing;
a vaporizing element in the housing;
an electrical power source in the housing;
a switch for switching on and off electrical power to the vaporizing element from the electrical power source;
a liquid reservoir in the housing;
a tube connecting the liquid reservoir to the vaporizing element;
a first valve, a second valve, and a pump associated with the tube, with the pump between the first and second valves; and
a lever pivotally supported on or in the housing and positioned to operate the first valve, the second valve, the pump and the switch, via pivoting movement of the lever with the first valve comprising a projection on the lever positioned to pinch the tube closed as the lever is pivoted to actuate the device.
10. A vapor delivery device comprising:
a housing;
a vaporizing element in the housing;
an electrical power source in the housing;
a switch for switching on and off electrical power to the vaporizing element from the electrical power source;
a liquid reservoir in the housing;
a tube connecting the liquid reservoir to the vaporizing element;
a first valve, a second valve, and a pump associated with the tube, with the pump between the first and second valves; and
a lever pivotally supported on or in the housing and positioned to operate the first valve, the second valve, the pump and the switch, via pivoting movement of the lever with the second valve including a post with the tube passing through an opening in the post and a spring urging a washer into contact with the tube.
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The field of the invention is vaporizing a liquid for inhalation. Various vaporizing devices have been used in the past. Still, disadvantages remain in the design and performance of vaporizing devices. These include variations in the dose of vapor delivered and leakage or performance failures unless the vaporizing device is maintained in an upright position during use, or during the packaging, shipping and storage of the device. In addition, with some vaporizing devices, the liquid may be subject to contamination, adulteration and/or evaporation under certain conditions.
Accordingly, it is an object of the invention to provide an improved vapor delivery system.
In one aspect, a vapor delivery device may have a vaporizing element and an electrical power source in a housing. A switch controls supply of electrical power to the vaporizing element from the electrical power source. A tube connects a liquid reservoir to the vaporizing element. A first valve, a second valve, and a pump are generally associated with the tube. A lever pivotally supported on or in the housing may be positioned to operate the first valve, the second valve, the pump and the switch, via pivoting movement of the lever. Other and further objects and advantages will become apparent from the following detailed description, which provides examples of embodiments of the invention. Persons of ordinary skill will readily be led to other additional examples of the invention that are not specifically described here, but are still intended to be within the scope of the invention.
Turning now in detail to the drawings, as shown in
As shown in
A tube 66 extends from the reservoir 64 to a lever valve 70 which may include a valve post 74, a valve spring 72 and valve washer 76. A valve section 80 of the tube 66 in this design extends through an opening the valve post 74, as shown in
Referring to
In use, the mouthpiece 24 is placed into the mouth and the user presses or squeezes the lever 28. The tube 66 is pre-filled or primed with liquid during manufacture. Referring to FIG. 4, as the lever 28 pivots down about the pivot 58, a pincher 86 located on a first section 90 of the lever 28 pivotally attached to the housing pinches the pump segment 67 of the tube 66 against an inside surface of the housing 20, adjacent to the pivot 58 and the reservoir 64. This temporarily closes off the tube 66 at the pincher 86. As the lever 28 continues to pivot down (or inward towards the centerline of the device) a ramp surface 88 on a second section 92 of the lever 28, flexibly attached to the first section 90 progressively squeezes the pump segment 67 of the tube 66 between the pincher 86 and the lever valve 70. This creates a squeegee type of movement which pumps liquid towards the lever valve 70 using a peristaltic action. As the lever 28 continues to pivot inwardly, posts on the lever press the valve washer 76 down against the force of the valve spring 72. This temporarily opens the lever valve 70 by allowing the valve section 80 of the tube 66 to open. With the valve section 80 of the tube open, and with liquid in the tube being pumped via the ramp surface 88, a bolus of liquid flows through the valve section 80 and the outlet segment 154 and into the wire coil 152.
An outlet segment 154 of the tube 66 extending out of the lever valve 70 towards the mouthpiece or back end of the device is inserted into the front end of a wire coil 152. Referring momentarily to
The tube 66 is connected to the reservoir 64 with a liquid-tight connection so that liquid can only flow from the reservoir only through tube 66. The tube 66 may be a resilient, flexible material such that its inner lumen can in general be completely flattened when compressed, and then generally recover to its original shape when released. A pump segment 67 of the tube 66 is positioned beneath the lever 28 and a fixed surface inside of the housing, which optionally may be part of the circuit board 82 that power management circuitry, is on. Locating features 112 may be provide in, on, or through the circuit board 82 to ensure desired positioning is maintained. The lever 28 is retained by lever pivot 116 and can pivot through a controlled range of motion.
The constant positive pressure exerted on the reservoir 64 by the springs 60 pressurizes the liquid in the tube 66. However, since the tube 66 is pinched closed by the pincher 86, no liquid flows out of the reservoir when the lever is depressed and the lever valve is opening. Rather, the liquid already present in the tube 66 between the pincher 86 and the lever valve 70 provides the measured bolus which is uniformly delivered to the wire coil.
The downward movement of the lever 28 also closes a switch 158 linked to or located on the circuit board 82. Electric current then flows from the batteries 44, or other power source, to the wire coil 152. The wire coil heats up causing the liquid to vaporize. The current supplied to the wire coil, and the temperature of the wire coil when operating, may be regulated by the circuit board, depending on the liquid used, the desired dose, and other factors. The switch 158 may be positioned to close only when the lever 28 is fully depressed. This avoids inadvertently heating the wire coil. It also delays heating the wire coil until the bolus of liquid is moved into the wire coil via the pivoting movement of the lever, to help prolong battery life. A “one-shot” control circuit, for example as shown in
As is apparent from this description, the liquid delivery system 30, using a linear peristaltic pumping action, delivers a fixed, repeatable bolus of liquid to vaporizing system 32 with each actuation of the device 20. The liquid delivery system 30 further seals the reservoir 64 between actuations via the pincher 86, maintains the contents of the reservoir in a pressurized state, and controls electric power delivery to the vaporizing system 32. The liquid delivery system is designed so that as liquid is used, air is not introduced into the system.
The diameter and length of the wire coil 152 forms a cylindrical volume within the inside diameter of the coil that is sufficient to capture a single expressed dose of liquid from the liquid delivery system. The adjacent loops of wire of the wire coil 152 may also be positioned so that liquid surface tension holds the liquid within the bore of the coil. This allows the device 20 to be used in any orientation, since gravity is not needed to keep the released dose of liquid in place.
The use of an open coil offers the further advantage that the vapor may be generated and escape anywhere along the length of the coil, without inadvertently affecting vaporization of the balance of the bolus of liquid in the coil. The wire coil also provides a large surface area for heat transfer and minimizes energy loss resulting from heating ancillary components.
Upon application of electric power, liquid in the coil vaporizes and passes through gaps between coils. The coil can be sized and shaped and positioned in the housing so that the vapor generated can be entrained into an air stream drawn through the device 20 when the user inhales on the mouthpiece. Inhale here means drawing the vapor at least into the mouth.
As shown in
Further rotation of lever 110 then compresses the lumen of the pump segment 67 of the tube 66. This pumps liquid from the pump segment 67 towards the lever valve 118. This movement also moves projections on the lever which push valve flanges 120 down, deflecting and opening the lever valve 118, and allowing a pressurized bolus of liquid to move through the tube and into the vaporizing system 32. The dotted lines in
When lever 110 is released, it pivots back up to its original position. As the lever returns, the lever valve 118 reseats first, sealing the back end of pump segment 67 of the tube 66 and preventing air from being drawn back into the pump segment. As the lever 110 continues to rotate clockwise, the pump segment 67 decompresses, creating a negative pressure within the tube lumen. Lastly, at pinch point 140 the tube 66 reopens, allowing pressurized liquid from the reservoir to enter, refilling pump segment with liquid to provide the next dose.
The volume of liquid expressed with each stroke can he controlled by selection of desired pump segment 67 tube diameter and length. Maintenance of a positive pressure on the liquid reservoir ensures that the system always stays primed with liquid, and that “short shots” resulting from air bubbles in the tube do not occur. Furthermore, sealing of the vaporizer system with a valve such as the valve 70 or 118 that is only actuated at the time of delivery, and positive pressure dispensing prevents inadvertent leakage of liquid irrespective of orientation of the device during storage or use.
A wide range of pulse durations may be selected. Using a typical ni-chrome wire coil, pulse durations ranging from approximately 0.2 to 2 seconds are sufficient to fully vaporize the bolus of liquid. When the voltage on pin 3 reaches the threshold for logic “0” (˜⅓ supply voltage), the logic levels switch and Q (pin 10) returns to a logic low level. Q2 is an emitter follower that provides current amplification to enable Q1 to be fully saturated during the desired current pulse. D1 and R4 provide a visual indication of the heater current. R2 is a “pull down” resistor for SW1, and C2 prevents induced noise from falsely triggering the circuit. Other choices of IC may be employed such as the Toshiba TC7WH123 depending upon battery voltage, package size, and cost.
The battery voltage gradually decreases over the lifespan of the device. For many applications, the circuit described in
In another alternative design, the electrical power system 34 may be configured to provide consistent power by timing the power to provide the minimum energy needed to vaporize the liquid. The power system may also be programmed to do this. For example, the electrical power system may be programmed to power the source down to the voltage required to vaporize the liquid, so as to extend its useful life. Here, the power source may include a capacitor that builds, retains and provides a charge necessary to vaporize the liquid to be vaporized, again, so as to extend the useful life of the power source.
In an additional alternative design shown in
Brass posts or similar contacts are attached to the printed circuit board 216 and to opposite ends of the coil 222. The button 208 has a pincher arm 238 positioned to pinch and close off flow in a tube 236 connecting a liquid reservoir to an outlet location on, adjacent to or overlying the wick 220. The tube 236 may be held in place by molded in tube clips 242 on the bridge 224. Arms 233 on a normally closed pinch valve 232 extend up through openings in the bridge 224. A valve spring 230 around a post 228 holds the valve 232 into the normally closed position. A bottom surface of the valve 232 may act as a switch with the printed circuit board 216, or actuate a separate switch on the printed circuit board 216, to switch on electrical current to the coil 222 when the button 208 is pressed.
In use, the vaporizing device 200 operates on the same principals as described above, with the following additions. A slot 210 may be provided in the housing to accommodate an insulating tab. The insulating tab is installed during manufacture and prevents electrical contact between the center contact 212 and the batteries. As a result, the device cannot be inadvertently turned on during shipping and storage. Battery life is therefore better preserved. Before operating the vaporizing device 200 for the first time, the user pulls the tab out of the slot 210. As shown in
Referring to
In each of the vaporizing devices described above, the open coil heater 152 or 222 of e.g., ni-chrome wire may be encased in a porous ceramic material, so that the vapor produced when the fluid is atomized must pass through the ceramic material in order to be ingested. The ceramic material can be manufactured with techniques that control the size of the pores through which the vapor will pass. This can help to regulate the size of the vapor molecules or droplets produced for inhalation. By controlling the amount of electrical power and the duration of power to the coil heater, the heater continues to vaporize the fluid at the heater until the vapor droplets or particles are small enough to pass through the ceramic material, effectively utilizing all the fluid delivered to the coil and controlling the dose in addition to regulating the molecule size. By regulating the size of the vapor molecule produced, the vaporizing devices can be used with more precision and with fluids and medicaments that require carefully controlled dosages particle sizes. In some cases, smaller molecules may be advantageous as they can be inhaled more deeply into the lungs, providing better a more effective delivery mechanism.
The wire coil heater may alternatively be encased in a heat resistant fabric-like material, so that the vapor must pass through the fabric to be ingested. The fabric can be manufactured with a desired mesh opening size, better regulate the size of the vapor particles delivered by the vaporizer. By, by controlling the amount of electrical power and the duration of power to the heater, the heater continues to vaporize the fluid delivered to the heater until the vapor particles are small enough to pass through the mesh of the fabric. This can help to effectively atomize and deliver all the fluid delivered to the heater, with little or no waste, in turn controlling the dose.
Although the switch 158 is described above as a mechanical contact switch, other forms of switches may optionally be used, including switches that optically or electrically sense the movement of position of an element, or a switch that senses the presence of liquid in the heater 150. In addition, though the lever and pinch valves are shown as clamping type of valves, other forms of mechanically or electrically operated valves may be used. Similarly, the peristaltic pumping action created by the pivoting movement of the lever may be optionally replaced with alternative forms of pumping or fluid movement. Various types of equivalent heating elements may also be used in place of the wire coils described. For example, solid state heating elements may be used. The heating element may also be replaced by alternative vaporizing elements, such as electro-hydrodynamic or piezo devices that can convert liquid into a vapor without heating. Thus, multiple embodiments and methods have been shown and described. Various modifications and substitutions may of course be made without departing from the spirit and scope of the invention. The invention, therefore, should not be limited except by the following claims and their equivalents.
Bartkowski, William, Goodman, Jack, O'Neill, William, Chong, Alexander
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Mar 09 2011 | GOODMAN, JACK | CHONG CORPORATION | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 025929 | /0565 | |
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